Supporting Data for Gradual Not Sudden Change: Multiple Sites of Functional Transition Across the Microvascular Bed by Kira Shaw (4467583)

“…<br></div><div><br></div><div>Abstract <br></div><div>In understanding the role of the neurovascular unit as both a biomarker and target for disease interventions, it is vital to appreciate how the function of different components of this unit change along the vascular tree. …”

Data_Sheet_1_The Proinflammatory Role of Guanylate-Binding Protein 5 in Inflammatory Bowel Diseases.docx by Yichen Li (200944)

“…In addition, GBP5 may upregulate inflammatory reactions through an inflammasome-mediated mechanism. Since GBP5 plays a proinflammatory role at the early steps of the inflammatory cascades of IBD pathogenesis, and is implicated in IBD patients of distinct genetic and environmental backgrounds, targeting GBP5 could be an effective strategy for the management of IBD.…”

THE IMPACT OF CLIMATE CHANGE ON THE ADAPTATION OF LOCAL CROP YIELD IN MAYUKWAYUKWA SETTLEMENT OF KAOMA DISTICT IN WESTERN PROVINCE by Chikondi Mbewe (17419309)

“…</p><p dir="ltr">The next steps involve addressing decreased rainfall in the Western province, likely attributed to human-induced activities like deforestation. …”

Data_Sheet_1_Gradual Not Sudden Change: Multiple Sites of Functional Transition Across the Microvascular Bed.pdf by Kira Shaw (11099383)

“…<p>In understanding the role of the neurovascular unit as both a biomarker and target for disease interventions, it is vital to appreciate how the function of different components of this unit change along the vascular tree. …”

Understanding and Improving the Kinetics of Bulk Carbonation on Sodium Carbonate by Tianyi Cai (1511026)

“…We find that the kinetics of Na₂CO₃ bulk carbonation is controlled by the <i>I</i>_H⁺/<i>V</i>_Na^– defect pair generation in Na₂CO₃; we predict that the kinetics can be enhanced by doping lithium into Na₂CO₃, which decreases the defect formation energy by 0.13 eV. This prediction was confirmed by our fixed-bed experiments, which found a 125% increase in the initial CO₂ absorption rate and a 29% increase in CO₂ uptake after 36 min exposure in 0.7 wt % (1.0 at. %) Li-doped Na₂CO₃ compared with undoped Na₂CO₃.…”

Understanding and Improving the Kinetics of Bulk Carbonation on Sodium Carbonate by Tianyi Cai (1511026)

“…We find that the kinetics of Na₂CO₃ bulk carbonation is controlled by the <i>I</i>_H⁺/<i>V</i>_Na^– defect pair generation in Na₂CO₃; we predict that the kinetics can be enhanced by doping lithium into Na₂CO₃, which decreases the defect formation energy by 0.13 eV. This prediction was confirmed by our fixed-bed experiments, which found a 125% increase in the initial CO₂ absorption rate and a 29% increase in CO₂ uptake after 36 min exposure in 0.7 wt % (1.0 at. %) Li-doped Na₂CO₃ compared with undoped Na₂CO₃.…”

Understanding and Improving the Kinetics of Bulk Carbonation on Sodium Carbonate by Tianyi Cai (1511026)

“…We find that the kinetics of Na₂CO₃ bulk carbonation is controlled by the <i>I</i>_H⁺/<i>V</i>_Na^– defect pair generation in Na₂CO₃; we predict that the kinetics can be enhanced by doping lithium into Na₂CO₃, which decreases the defect formation energy by 0.13 eV. This prediction was confirmed by our fixed-bed experiments, which found a 125% increase in the initial CO₂ absorption rate and a 29% increase in CO₂ uptake after 36 min exposure in 0.7 wt % (1.0 at. %) Li-doped Na₂CO₃ compared with undoped Na₂CO₃.…”

Understanding and Improving the Kinetics of Bulk Carbonation on Sodium Carbonate by Tianyi Cai (1511026)

“…We find that the kinetics of Na₂CO₃ bulk carbonation is controlled by the <i>I</i>_H⁺/<i>V</i>_Na^– defect pair generation in Na₂CO₃; we predict that the kinetics can be enhanced by doping lithium into Na₂CO₃, which decreases the defect formation energy by 0.13 eV. This prediction was confirmed by our fixed-bed experiments, which found a 125% increase in the initial CO₂ absorption rate and a 29% increase in CO₂ uptake after 36 min exposure in 0.7 wt % (1.0 at. %) Li-doped Na₂CO₃ compared with undoped Na₂CO₃.…”

Understanding and Improving the Kinetics of Bulk Carbonation on Sodium Carbonate by Tianyi Cai (1511026)

“…We find that the kinetics of Na₂CO₃ bulk carbonation is controlled by the <i>I</i>_H⁺/<i>V</i>_Na^– defect pair generation in Na₂CO₃; we predict that the kinetics can be enhanced by doping lithium into Na₂CO₃, which decreases the defect formation energy by 0.13 eV. This prediction was confirmed by our fixed-bed experiments, which found a 125% increase in the initial CO₂ absorption rate and a 29% increase in CO₂ uptake after 36 min exposure in 0.7 wt % (1.0 at. %) Li-doped Na₂CO₃ compared with undoped Na₂CO₃.…”

Understanding and Improving the Kinetics of Bulk Carbonation on Sodium Carbonate by Tianyi Cai (1511026)

“…We find that the kinetics of Na₂CO₃ bulk carbonation is controlled by the <i>I</i>_H⁺/<i>V</i>_Na^– defect pair generation in Na₂CO₃; we predict that the kinetics can be enhanced by doping lithium into Na₂CO₃, which decreases the defect formation energy by 0.13 eV. This prediction was confirmed by our fixed-bed experiments, which found a 125% increase in the initial CO₂ absorption rate and a 29% increase in CO₂ uptake after 36 min exposure in 0.7 wt % (1.0 at. %) Li-doped Na₂CO₃ compared with undoped Na₂CO₃.…”